CN108649959A - A kind of digital analog converter and digital power amplifier subsystem - Google Patents
A kind of digital analog converter and digital power amplifier subsystem Download PDFInfo
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- CN108649959A CN108649959A CN201810889616.7A CN201810889616A CN108649959A CN 108649959 A CN108649959 A CN 108649959A CN 201810889616 A CN201810889616 A CN 201810889616A CN 108649959 A CN108649959 A CN 108649959A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03M—CODING; DECODING; CODE CONVERSION IN GENERAL
- H03M1/00—Analogue/digital conversion; Digital/analogue conversion
- H03M1/66—Digital/analogue converters
- H03M1/74—Simultaneous conversion
- H03M1/742—Simultaneous conversion using current sources as quantisation value generators
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/30—Modifications of amplifiers to reduce influence of variations of temperature or supply voltage or other physical parameters
- H03F1/301—Modifications of amplifiers to reduce influence of variations of temperature or supply voltage or other physical parameters in MOSFET amplifiers
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/30—Modifications of amplifiers to reduce influence of variations of temperature or supply voltage or other physical parameters
- H03F1/303—Modifications of amplifiers to reduce influence of variations of temperature or supply voltage or other physical parameters using a switching device
- H03F1/304—Modifications of amplifiers to reduce influence of variations of temperature or supply voltage or other physical parameters using a switching device and using digital means
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/32—Modifications of amplifiers to reduce non-linear distortion
- H03F1/3205—Modifications of amplifiers to reduce non-linear distortion in field-effect transistor amplifiers
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F3/00—Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
- H03F3/181—Low-frequency amplifiers, e.g. audio preamplifiers
- H03F3/183—Low-frequency amplifiers, e.g. audio preamplifiers with semiconductor devices only
- H03F3/185—Low-frequency amplifiers, e.g. audio preamplifiers with semiconductor devices only with field-effect devices
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F3/00—Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
- H03F3/20—Power amplifiers, e.g. Class B amplifiers, Class C amplifiers
- H03F3/21—Power amplifiers, e.g. Class B amplifiers, Class C amplifiers with semiconductor devices only
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F2200/00—Indexing scheme relating to amplifiers
- H03F2200/03—Indexing scheme relating to amplifiers the amplifier being designed for audio applications
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Abstract
This application discloses a kind of digital analog converter and digital power amplifier subsystems, the first switch of the digital analog converter, second switch, the clock feed-through effect and channel charge injection phenomenon that third switchs and the 4th switch generates in switching process will not cross the first current source and the second current source loads in the output signal of digital analog converter, so as to avoid due to first switch, second switch, harmful effect of the clock feed-through effect and channel charge injection phenomenon that third switchs and the 4th switch generates in switching process to the output signal of digital analog converter;So that first switch, second switch, third switch and the size of the 4th switch can not be limited, the switching tube of large-size may be used to switch as first switch, second switch, third switch and the 4th, solve the problems, such as due to first switch, second switch, third switch and the 4th switch consume excessive voltage drop and so that the first current source and the second current source are operated in linear zone.
Description
Technical field
The application designs technical field of circuit design, more specifically to a kind of digital analog converter and digital work(
Put subsystem.
Background technology
Digital power amplifier has the characteristics that the small, low noise of distortion, dynamic range be big, strong antijamming capability, in the transparent of sound quality
Degree parses power, and the advantage in terms of quiet, low frequency the shock dynamics of background substantially exceeds traditional analog amplifier and class D
Power amplifier.With DVD home theaters, mini audio system, set-top box, PC, LCD TV, flat-panel monitor and mobile electricity
The development with rapid changepl. never-ending changes and improvements of the consumer products such as words, the especially new source of sound specification of some high sample frequencys such as SACD, DVD Audio
Appearance and sound system from stereo to the evolution of multichannel surrounding system, all accelerate the development of digital power amplifier.In number
Word power domain, now with occurring a kind of new noun " pure digi-tal power amplifier " for HIFI enthusiast, it supports many numbers
Word audio-format signal inputs, such as I2S, TDM, it can pass through number DSP processing, realize abundant sound effect algorithms, have very
Strong RF anti-interference abilities on mobile phone there is natural advantage, digital signal will not bring the phase court of a feudal ruler in transmission process
Late, phase distortion, intermodulation distortion etc., the benefit of sense of hearing, which is exactly sound, can be more fully apparent from, position more accurate, sound closer to really.
Two digital power amplifier subsystems are generally included in digital power amplifier system, two digital power amplifier subsystems first are used respectively
In receiving the first input signal and the second input signal, the first input signal and the second input signal are by digital module to receiving
The digital input signals such as I2S, TDM convert and obtain after audio effect processing, digital gain amplification, digital filtering;So latter two
Digital power amplifier subsystem carries out digital-to-analogue conversion processing (Digital- to the first input signal and the second input signal respectively
To-Analog Conversion, DAC) analog signal is obtained afterwards, and a series of waveform processings are carried out to the analog signal of acquisition
Afterwards, PWM square-wave signals are obtained, realize the amplification of analog gain;The square-wave signal of last the two digital power amplifier subsystems output
After the low-frequency filter characteristics of low-pass filtering or loud speaker itself, audio signal is restored.In this whole process, to first
What input signal and the second input signal carried out digital-to-analogue conversion processing is the digital analog converter of digital power amplifier subsystem.
Limitation of the digital analog converter in the prior art due to circuit structure so that it receives the switch of input signal
The size of pipe cannot be too big, and the parasitic capacitance otherwise generated between the drain electrode and source electrode of switching tube can become larger, in switching process
Clock feed-through effect and the channel charge injection of generation can increase, and bad shadow is generated to the output signal of digital analog converter
It rings, to generate harmful effect to the performance of entire digital power amplifier system;And the clock feedback in order to avoid switching tube in switch
Logical effect, the size of the switching tube of digital analog converter can only design it is smaller so that the resistance of these switching tubes compared with
Greatly, certain voltage drop can be consumed on these switching tubes, when the supply voltage of digital analog converter is relatively low, can make total
The current source of word analog converter is operated in linear zone, to give output current value and the equivalent output resistance of digital analog converter
Anti- generation harmful effect, finally brings harmful effect to the performance of digital analog converter.
Invention content
In order to solve the above technical problems, this application provides a kind of digital analog converter and digital power amplifier subsystem, with
Solution is smaller since the size of the switching tube in digital analog converter can only design, and to the performance of digital analog converter
The problem of bringing harmful effect.
To realize the above-mentioned technical purpose, the embodiment of the present application provides following technical solution:
A kind of digital analog converter, is applied to digital power amplifier subsystem, and the digital analog converter includes:First opens
Pass, second switch, third switch, the 4th switch, the first current source and the second current source;Wherein,
For receiving drive voltage signal, the other end is opened with first current source and third for one end of the first switch
One end of pass connects, and the one end of the third switch far from first current source is for receiving common mode voltage signal;
First current source is connect far from described first switch one end with second current source, second current source
It is connected simultaneously with the second switch and the 4th switch far from first current source one end;
The second switch terminates fixed current potential far from second current source one, and the 4th switch is far from described second
Current source one end is for receiving the common mode voltage signal;
The on off state of the first switch and the 4th switch is controlled by the first input signal, the second switch and third
The on off state of switch is controlled by the second input signal, and the switching sequence and described second of the first switch and the 4th switch
The switching sequence of switch and third switch is opposite;
First current source is the first transistor;
Second current source is second transistor.
Optionally, the first switch and the 4th switch are the first transistor npn npn;
The second switch and third switch are the second transistor npn npn;
First input signal and the second input signal are the identical square-wave signal of phase.
Optionally, the first switch, second switch, third switch and the 4th switch are the first transistor npn npn or are
Second transistor npn npn;
First input signal and the square-wave signal that the second input signal is opposite in phase.
Optionally, first transistor npn npn is P-type transistor;
Second transistor npn npn is N-type transistor.
Optionally, first transistor npn npn is P-type TFT;
Second transistor npn npn is N-type TFT.
Optionally, the grid of the first transistor is for receiving the first bias voltage, the source electrode of the first transistor
The first switch and third switch are connected, the drain electrode of the first transistor connects the drain electrode of the second transistor;
The grid of the second transistor for receive the second bias voltage, the second transistor source electrode connection described in
Second switch and the 4th switch;
The first transistor the first switch in the open state, generate by the first transistor drain electrode flow to
First electric current of the source electrode of the first transistor;
The second transistor the second switch in the open state, generate by second transistor drain electrode flow to
Second electric current of the source electrode of second transistor, first electric current and the second electric current are image current;
The first transistor is p type field effect transistor, and the second transistor is n type field effect transistor.
Optionally, first bias voltage and the second bias voltage are generated by the same bandgap voltage reference.
A kind of digital power amplifier subsystem, including:Digital analog converter as described in any one of the above embodiments, amplifier, integral
Device, PWM comparators, driver, first resistor and the first capacitance;Wherein,
The signal output end of the digital analog converter is connect with the first signal input part of the amplifier, described to put
The second signal input terminal of big device is for receiving common mode voltage signal, the signal output end of the amplifier and the integrator
Signal input part connects;
The signal output end of the integrator is connect with the signal input part of the PWM comparators, the PWM comparators
Signal output end is connect with the signal input part of the driver, and the signal output end of the driver is as the digital power amplifier
The signal output end of subsystem;
One end of the first resistor is connected to the connecting node of the digital analog converter and the amplifier, and described
Another signal output end for being terminated at the driver of one resistance;
One end of first capacitance is connected to the connecting node of the amplifier and the digital analog converter, and described
Another connecting node for being terminated at the amplifier and the integrator of one capacitance.
Optionally, the two of the drive voltage signal that the common mode voltage signal receives for the digital analog converter/
One or one third.
It can be seen from the above technical proposal that the embodiment of the present application provides a kind of digital analog converter and digital power amplifier
Subsystem, wherein first switch and the third switch of the digital analog converter are located at the first current source far from digital simulation
It is remote that the signal output end side of converter, the second switch of the digital analog converter and the 4th switch are located at the second current source
Signal output end side from digital analog converter, so first switch, second switch, third switch and the 4th switch
Clock feed-through effect and channel charge the injection phenomenon generated in switching process will not cross the first current source and the second electric current
Source loads in the output signal of digital analog converter, so as to avoid due to first switch, second switch, third switch and
The clock feed-through effect and channel charge that 4th switch generates in switching process inject phenomenon to the defeated of digital analog converter
Go out the harmful effect of signal;So that first switch, second switch, third switch and the size of the 4th switch will not be limited
System, the switching tube that large-size may be used are switched as the first switch, second switch, third switch and the 4th, are solved
Due to first switch, second switch, third switch and the 4th switch consume excessive voltage drop and make first current source and
The problem of second current source is operated in linear zone.
Also, it, can be in first switch and the second switch by off state due to the presence of third switch and the 4th switch
Transformation can be such that the first current source and the second current source opens faster when being in an open state, reduce electric current recovery time and
The voltage ripple of the source electrode of first current source reduces the non-linear of entire circuit, and avoids unnecessary delay.
Description of the drawings
In order to illustrate the technical solutions in the embodiments of the present application or in the prior art more clearly, to embodiment or will show below
There is attached drawing needed in technology description to be briefly described, it should be apparent that, the accompanying drawings in the following description is only this
The embodiment of application for those of ordinary skill in the art without creative efforts, can also basis
The attached drawing of offer obtains other attached drawings.
Fig. 1 is a kind of structural schematic diagram for digital analog converter that one embodiment of the application provides;
Fig. 2 is a kind of structural schematic diagram for digital analog converter that another embodiment of the application provides;
Fig. 3 is a kind of structural schematic diagram for digital power amplifier subsystem that one embodiment of the application provides;
Fig. 4 is the waveform comparison of a kind of first input signal and the second input signal that one embodiment of the application provides
Schematic diagram;
Fig. 5 be the application one embodiment provide first input signal of one kind, the second input signal, common-mode voltage believe
Number, the waveform comparison schematic diagram of the output signal of the output signal of digital analog converter and digital power amplifier subsystem;
Fig. 6 is the defeated of a kind of amplifier, integrator, PWM comparators and the driver that one embodiment of the application provides
Go out the waveform comparison schematic diagram of signal.
Specific implementation mode
Below in conjunction with the attached drawing in the embodiment of the present application, technical solutions in the embodiments of the present application carries out clear, complete
Site preparation describes, it is clear that described embodiments are only a part of embodiments of the present application, instead of all the embodiments.It is based on
Embodiment in the application, it is obtained by those of ordinary skill in the art without making creative efforts every other
Embodiment shall fall in the protection scope of this application.
The embodiment of the present application provides a kind of digital analog converter, as shown in Figure 1, it is applied to digital power amplifier subsystem,
The digital analog converter includes:First switch S1, second switch S2, third switch S3, the 4th switch S4, the first current source
IDAC1 and the second current source IDAC2;Wherein,
One end of the first switch S1 is for receiving drive voltage signal, the other end and the first current source IDAC1
It is connected with one end of third switch S3, the one end of the third switch S3 far from the first current source IDAC1 is for receiving altogether
Mode voltage signal;
The first current source IDAC1 is connect far from the one end the first switch S1 with the second current source IDAC2, institute
State the second current source IDAC2 far from described one end first current source IDAC1 simultaneously with the second switch S2 and the 4th switch S4
Connection;
The second switch S2 terminates fixed current potential far from the second current source IDAC2 mono-, and the 4th switch S4 is remote
From described one end second current source IDAC2 for receiving the common mode voltage signal;
The on off state of the first switch S1 and the 4th switch S4 is controlled by the first input signal PWM_P, and described second
The on off state of switch S2 and third switch S3 are controlled by the second input signal/PWM_P, and the first switch S1 and the 4th is opened
The switching sequence for closing S4 is opposite with the switching sequence of the second switch S2 and third switch S3;
As shown in Fig. 2, the first current source IDAC1 is the first transistor MP1;
The second current source IDAC2 is second transistor MN1.
With reference to figure 1 and Fig. 2, optionally, the fixed current potential can be that (the i.e. described second switch S2 is far from described for zero potential
Second one end current source IDAC2 is grounded GND).In Fig. 1, DAV_VO indicates the signal of the digital analog converter output;
VDD indicates the drive voltage signal;VCM indicates the common mode voltage signal.
In the present embodiment, the first input signal PWM_P and the second input signal/PWM_P controls described first are opened
Close the on off state of S1, second switch S2, third switch S3 and the 4th switch S4.The first input signal PWM_P and second
Input signal/PWM_P passes through sound by the digital module in digital power amplifier system to digital input signals such as I2S, TDM for receiving
It is obtained after effect processing, digital gain amplification and digital filtering, usually pwm signal, i.e. square-wave signal.
The first switch S1 and the switching sequence of the 4th switch S4 and opening for the second switch S2 and third switch S3
Close sequential refer on the contrary, within the same period, when the first switch S1 and the 4th switch S4 in the open state, it is described
Second switch S2 and third switch S3 are off state;When the first switch S1 and the 4th switch S4 are off state
When, the second switch S2 and third switch S3 are in the open state.The electricity of the first current source IDAC1 and second is enabled in this way
The image current that stream source IDAC2 is generated is exported as output signal.
In the present embodiment, the first switch S1 of the digital analog converter and third switch S3 is located at the first current source
Signal output end sides of the IDAC1 far from digital analog converter, the second switch S2 of the digital analog converter and the 4th
Switch S4 is located at signal output end sides of the second current source IDAC2 far from digital analog converter, so first switch
The clock feed-through effect and channel charge that S1, second switch S2, third switch S3 and the 4th switch S4 are generated in switching process
Injection phenomenon will not cross the first current source IDAC1 and the second current source IDAC2 loads are believed in the output of digital analog converter
In number, produced in switching process so as to avoid due to first switch S1, second switch S2, third switch S3 and the 4th switch S4
The harmful effect of raw clock feed-through effect and channel charge injection phenomenon to the output signal of digital analog converter;And then make
The size for obtaining first switch S1, second switch S2, third switch S3 and the 4th switch S4 can not be limited, and may be used larger
The switching tube of size is solved as the first switch S1, second switch S2, third switch S3 and the 4th switch S4 due to
One switch S1, second switch S2, third switch S3 and the 4th switch S4 consume excessive voltage drop and make the first current source
The problem of IDAC1 and the second current source IDAC2 are operated in linear zone.
Also, due to the presence of third switch S3 and the 4th switch S4, can first switch S1 and second switch S2 by
When off state transformation is in an open state, the first current source IDAC1 and the second current source IDAC2 can be made to open faster, subtracted
The voltage ripple of the source electrode of the recovery time of low current and the first current source IDAC1, reduces the non-linear of entire circuit, and avoid
Unnecessary delay.
It can make the first electric current when first switch S1 and second switch S2 is in an open state by off state transformation
Source IDAC1 and the second current source IDAC2 are opened faster, reduce the source electrode of the recovery time and the first current source IDAC1 of electric current
Voltage ripple, reduce the non-linear of entire circuit, and avoid unnecessary delay.
The first switch S1, second switch S2, third switch S3 and the 4th switch S4 switching sequence can lead on the contrary
Cross the concrete type and the first input signal of control first switch S1, second switch S2, third switch S3 and the 4th switch S4
The phase of PWM_P and the second input signal/PWM_P is realized.Specifically, in one embodiment of the application, described first
Switch S1 and the 4th switch S4 is the first transistor npn npn;
The second switch S2 and third switch S3 is the second transistor npn npn;
The first input signal PWM_P and the second input signal/PWM_P is the identical square-wave signal of phase.
In addition, in the alternative embodiment of the application, the first switch S1, second switch S2, third switch S3
It can also be the first transistor npn npn with the 4th switch S4 or be the second transistor npn npn;
The first input signal PWM_P and the second input signal/PWM_P is the square-wave signal of opposite in phase.
In the present embodiment, the first switch S1, second switch S2, third switch S3 and the 4th switch S4 are type phase
Same transistor, when receiving high level or low level signal at the same time, state in which is identical, at this point, the first switch S1
The second input received with the 4th switch S4 the first input signal PWM_P received the and second switch S2 and third switch S3
Signal/PWM_P needs the square-wave signal for opposite in phase, to ensure the switching sequence of the first switch S1 and the 4th switch S4
It is opposite with the switching sequence of the second switch S2 and third switch S3.
Optionally, first transistor npn npn is P-type transistor;
Second transistor npn npn is N-type transistor.
Optionally, first transistor npn npn is P-type TFT (Thin Film Transistor, TFT);
Second transistor npn npn is N-type TFT.
On the basis of the above embodiments, a kind of specifically the first electricity is provided in the specific embodiment of the application
The electric connection mode of stream source IDAC1 and the second current source IDAC2, as shown in Fig. 2, the grid of the first transistor MP1 is used for
The source electrode for receiving the first bias voltage VBP, the first transistor MP1 connects the first switch S1 and third switch
The drain electrode of S3, the first transistor MP1 connect the drain electrode of the second transistor MN1;
The grid of the second transistor MN1 is for receiving the second bias voltage VBN, the source of the second transistor MN1
Pole connects the second switch S2 and the 4th switch S4;
The first transistor MP1 the first switch S1 in the open state, generate by the first transistor MP1's
Drain electrode flows to the first electric current of the source electrode of the first transistor MP1;
The second transistor MN1 the second switch S2 in the open state, generate by second transistor MN1's
Drain electrode flows to the second electric current of the source electrode of second transistor MN1, and first electric current and the second electric current are image current;
The first transistor MP1 is p type field effect transistor, and the second transistor MN1 is N-type field effect transistor
Pipe.
Wherein, the first bias voltage VBP is used to the first transistor MP1 being biased in working condition, and described second partially
Voltage VBN is set for the second transistor MN1 to be biased in working condition.
Due to the presence of third switch S3 and the 4th switch S4, it is in and beats when first switch S1 shutdowns and third switch S3
During open state, the drain voltage of the first transistor MP1 is maintained at reference voltage level, we can with design reference voltage value with
The difference of the bias voltage value of the first transistor MP1 less than the first transistor MP1 cut-in voltage absolute value, so as to so that
No current in the first transistor MP1 is obtained to flow through, when first switch S1 third switch S3 in the open state are off state,
The first transistor MP1 can be opened quickly, generate the first electric current, reduce recovery time and the first transistor of the first electric current
The voltage ripple of the source electrode of MP1 to be conducive to reduce the non-linear of circuit, and avoids unnecessary delay.
Likewise, when second switch S2 shutdown and the 4th switch S4 periods in the open state, second transistor MN1's
Drain voltage is maintained at reference voltage level, what we can be received with the grid of design reference voltage value and second transistor MN1
The absolute value of cut-in voltage of the difference of second bias voltage VBN values less than second transistor MN1, so that second is brilliant
No current flows through in body pipe MN1, when second switch S2 the 4th switch S4 in the open state are off state, the second crystal
Pipe MN1 can be opened quickly, generate the second electric current, reduce the source electrode of the recovery time and second transistor MN1 of the second electric current
Voltage ripple and avoid unnecessary delay to be conducive to reduce the non-linear of circuit.
Optionally, the first bias voltage VBP and the second bias voltage VBN are produced by the same bandgap voltage reference
It is raw.The first bias voltage VBP and the second bias voltage VBN can be ensured by the generation of the same bandgap voltage reference in work
The second electricity that the first electric current and the second current source IDAC2 that skill changes under different temperatures, the first current source IDAC1 is generated generate
Flow it is almost equal, to improve the stability of the digital analog converter output signal.
Correspondingly, the embodiment of the present application also provides a kind of digital power amplifier subsystems, as shown in figure 3, including:Such as above-mentioned
Digital analog converter 10 described in one embodiment, amplifier 20, integrator 30, PWM comparators 40, the 50, first electricity of driver
Hinder RF and the first capacitance C1;Wherein,
The signal output end of the digital analog converter 10 is connect with the first signal input part of the amplifier 20, institute
The second signal input terminal of amplifier 20 is stated for receiving common mode voltage signal, the signal output end of the amplifier 20 with it is described
The signal input part of integrator 30 connects;
The signal output end of the integrator 30 is connect with the signal input part of the PWM comparators 40, and the PWM compares
The signal output end of device 40 is connect with the signal input part of the driver 50, and the signal output end of the driver 50 is as institute
State the signal output end of digital power amplifier subsystem;
An end of the first resistor RF is connected to the connecting node of the digital analog converter 10 and the amplifier 20,
Another signal output end for being terminated at the driver 50 of the first resistor RF;
An end of the first capacitance C1 is connected to the connecting node of the amplifier 20 and the digital analog converter 10,
Another connecting node for being terminated at the amplifier 20 and the integrator 30 of the first capacitance C1.
In figure 3, VCM indicates that the common-mode voltage, AMP_V1 indicate that the output signal of the amplifier, VOP indicate institute
State the output signal of digital power amplifier subsystem.
In the specific embodiment of the application, it is designed as the first input signal PWM_P and the second input signal/PWM_
The waveform diagram of the opposite in phase of P, the first input signal PWM_P and the second input signal/PWM_P with reference to figure 4, and
When the first input signal PWM_P is in high level, the first switch S1 and the 4th switch S4 are opened, and at this time described second
Input signal/PWM_P is in low level, the second switch S2 and the S3 shutdowns of third switch;When first input signal
When PWM_P is in low level, the first switch S1 and the 4th switch S4 shutdowns, the second input signal/PWM_P is in height at this time
Level, the second switch S2 and third switch S3 are opened.
The first input signal PWM_P, the second input signal/PWM_P, common mode voltage signal, the digital simulation turn
The comparison of wave shape schematic diagram of the output signal of parallel operation 10 and the output signal of digital power amplifier subsystem is with reference to figure 5, in Fig. 5, VCM tables
Show that the waveform of the common mode voltage signal, DAC_VO indicate the waveform of the output signal of the digital analog converter 10, VOP tables
Show the waveform of the output signal of the digital power amplifier subsystem;From figure 5 it can be seen that due in loop each device it is intrinsic
There is certain consolidate in the output signal of the digital analog converter 10 and the output signal of digital power amplifier subsystem in delay
There is delay LD (Loop Delaytime).
When the first switch S1 and the 4th switch S4 are opened, and the second switch S2 and third switch S3 are turned off, this
When the first current source IDAC1 export the first electric current to first resistor RF and the first capacitance C1 (close to the digital analog converter
The pole plate of 10 sides) it charges, amplifier 20 is to (the poles far from 10 side of the digital analog converter the first capacitance C1
Plate) it discharges, voltage of the amplifier 20 far from 10 one end of the digital analog converter reduces, and passes through integrator 30, PWM comparators
40 and driver 50 export signal be low level.When the first switch S1 and the 4th switch S4 shutdowns, the second switch
When S2 and third switch S3 are opened, the second current source IDAC2 exports the second electric current to first resistor RF and the first capacitance C1 at this time
(pole plate close to 10 side of the digital analog converter) discharges, and amplifier 20 is to the first capacitance C1 (far from the number
The pole plate of 10 side of word analog converter) charging, voltage raising of the amplifier 20 far from 10 one end of the digital analog converter,
It is high level by the signal that integrator 30, PWM comparators 40 and driver 50 export.The one of the first input signal PWM_P
In a period, the waveform that amplifier 20, integrator 30, PWM comparators 40 and driver 50 respectively export is with reference to figure 6, in Fig. 6
In, sine wave AMP_V0 indicates that the waveform that the amplifier 20 exports, triangular wave AMP_V1 indicate what the integrator 30 exported
Waveform, square-wave signal PWMQ indicate that the waveform that the PWM comparators 40 export, square wave VOP indicate what the driver 50 exported
Signal;As can be seen that the signal that amplifier 20 exports forms triangular wave from Fig. 4 and Fig. 6.The signal that driver 50 exports is side
Wave, and the driving capability of the square-wave signal of the output of driver 50 is better than the driving energy of the square-wave signal of the output of PWM comparators 40
Power.The signal that driver 50 exports restores audio signal after the low-frequency filter characteristics of low-pass filtering or loud speaker itself.
In the digital power amplifier subsystem, the common mode voltage signal can be that the digital analog converter 10 receives
Drive voltage signal VDD half or one third, as long as ensureing the drive received in the digital analog converter 10
The first transistor MP1 in the variation range of dynamic voltage signal VDD as the first current source IDAC1 does not enter linear zone.
Since feedback loop gain is very big, the value of differential signal (DAC_VO-VCM) will very little, so DAC_VO is with respect to VCM or more
The ripple very little of fluctuation, thus digital analog converter 10 export signal DAC_VO centered on common mode voltage signal VCM into
The non-linear distortion of small fluctuation above and below row, digital power amplifier subsystem can improve the power supply inhibition energy of digital power amplifier subsystem
Power.
In digital power amplifier subsystem shown in Fig. 3, the first input signal PWM_P or the second input signal/PWM_P to number
The gain of the signal of word power amplifier subsystem final output is:AV=2 × (2 × Din-1) × IDAC × RF, wherein Din first
The high level duty ratio of input signal PWM_P or the second input signal/PWM_P, IDAC indicate the first current source IDAC1 or
The current value that second current source IDAC2 is generated, RF indicate the resistance value of the first resistor RF.
In conclusion the embodiment of the present application provides a kind of digital analog converter and digital power amplifier subsystem, wherein institute
First switch and the third switch for stating digital analog converter are defeated positioned at signal of first current source far from digital analog converter
Outlet side, the second switch of the digital analog converter and the 4th switch are located at the second current source far from digital-to-analogue conversion
The signal output end side of device, so first switch, second switch, third switch and the 4th switch produce in switching process
Raw clock feed-through effect and channel charge injection phenomenon will not cross the first current source and the load of the second current source in digital mould
In the output signal of quasi- converter, switched so as to avoid due to first switch, second switch, third switch and the 4th switch
Bad shadow of clock feed-through effect and channel charge the injection phenomenon generated in the process to the output signal of digital analog converter
It rings;So that first switch, second switch, third switch and the 4th switch size can not be limited, may be used compared with
Large-sized switching tube is switched as the first switch, second switch, third switch and the 4th, is solved since first opens
Pass, second switch, third switch and the 4th switch consume excessive voltage drop and make the first current source and the second current source work
Make the linear zone the problem of.
Also, it, can be in first switch and the second switch by off state due to the presence of third switch and the 4th switch
Transformation can be such that the first current source and the second current source opens faster when being in an open state, reduce electric current recovery time and
The voltage ripple of the source electrode of first current source reduces the non-linear of entire circuit, and avoids unnecessary delay.
Each embodiment is described by the way of progressive in this specification, the highlights of each of the examples are with other
The difference of embodiment, just to refer each other for identical similar portion between each embodiment.
The foregoing description of the disclosed embodiments enables professional and technical personnel in the field to realize or use the application.
Various modifications to these embodiments will be apparent to those skilled in the art, as defined herein
General Principle can in other embodiments be realized in the case where not departing from spirit herein or range.Therefore, the application
It is not intended to be limited to the embodiments shown herein, and is to fit to and the principles and novel features disclosed herein phase one
The widest range caused.
Claims (9)
1. a kind of digital analog converter, which is characterized in that be applied to digital power amplifier subsystem, the digital analog converter packet
It includes:First switch, second switch, third switch, the 4th switch, the first current source and the second current source;Wherein,
One end of the first switch is switched for receiving drive voltage signal, the other end with first current source and third
One end connects, and the one end of the third switch far from first current source is for receiving common mode voltage signal;
First current source is connect far from described first switch one end with second current source, and second current source is separate
First current source one end is connected with the second switch and the 4th switch simultaneously;
The second switch terminates fixed current potential far from second current source one, and the 4th switch is far from second electric current
Source one end is for receiving the common mode voltage signal;
The on off state of the first switch and the 4th switch is controlled by the first input signal, the second switch and third switch
On off state controlled by the second input signal, and switching sequence and the second switch of the first switch and the 4th switch
And the switching sequence of third switch is opposite;
First current source is the first transistor;
Second current source is second transistor.
2. digital analog converter according to claim 1, which is characterized in that the first switch and the 4th switch are
First transistor npn npn;
The second switch and third switch are the second transistor npn npn;
First input signal and the second input signal are the identical square-wave signal of phase.
3. digital analog converter according to claim 1, which is characterized in that the first switch, second switch, third
Switch and the 4th switch are the first transistor npn npn or are the second transistor npn npn;
First input signal and the square-wave signal that the second input signal is opposite in phase.
4. according to Claims 2 or 3 any one of them digital analog converter, which is characterized in that first transistor npn npn
For P-type transistor;
Second transistor npn npn is N-type transistor.
5. digital analog converter according to claim 4, which is characterized in that first transistor npn npn is p-type film
Transistor;
Second transistor npn npn is N-type TFT.
6. digital analog converter according to claim 1, which is characterized in that the grid of the first transistor is for connecing
The first bias voltage is received, the source electrode of the first transistor connects the first switch and third switch, and described first is brilliant
The drain electrode of body pipe connects the drain electrode of the second transistor;
The grid of the second transistor is for receiving the second bias voltage, the source electrode connection described second of the second transistor
Switch and the 4th switch;
The first transistor the first switch in the open state, generate and by the drain electrode of the first transistor flow to first
First electric current of the source electrode of transistor;
The second transistor the second switch in the open state, generate and by the drain electrode of second transistor flow to second
Second electric current of the source electrode of transistor, first electric current and the second electric current are image current;
The first transistor is p type field effect transistor, and the second transistor is n type field effect transistor.
7. digital analog converter according to claim 6, which is characterized in that first bias voltage and the second biasing
Voltage is generated by the same bandgap voltage reference.
8. a kind of digital power amplifier subsystem, which is characterized in that including:As claim 1-7 any one of them digital simulations turn
Parallel operation, amplifier, integrator, PWM comparators, driver, first resistor and the first capacitance;Wherein,
The signal output end of the digital analog converter is connect with the first signal input part of the amplifier, the amplifier
Second signal input terminal for receiving common mode voltage signal, the signal of the signal output end of the amplifier and the integrator
Input terminal connects;
The signal output end of the integrator is connect with the signal input part of the PWM comparators, the signal of the PWM comparators
Output end is connect with the signal input part of the driver, and the signal output end of the driver is as the digital power amplifier subsystem
The signal output end of system;
One end of the first resistor is connected to the connecting node of the digital analog converter and the amplifier, first electricity
Another signal output end for being terminated at the driver of resistance;
One end of first capacitance is connected to the connecting node of the amplifier and the digital analog converter, first electricity
Another connecting node for being terminated at the amplifier and the integrator held.
9. digital power amplifier subsystem according to claim 8, which is characterized in that the common mode voltage signal is the number
The half or one third for the drive voltage signal that analog converter receives.
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Address after: Room 1201, No.2, Lane 908, Xiuwen Road, Minhang District, Shanghai, 201199 Patentee after: SHANGHAI AWINIC TECHNOLOGY Co.,Ltd. Country or region after: China Address before: Room 303-39, building 33, 680 Guiping Road, Xuhui District, Shanghai 200233 Patentee before: SHANGHAI AWINIC TECHNOLOGY Co.,Ltd. Country or region before: China |